KR19990031630A - 4-electrode PD drive - Google Patents

Abstract

The present invention relates to the configuration of electrodes required for PDP discharge in a plasma display panel television. The PDP panel having a three-electrode structure forms a discharge between the S electrode and the Y electrode. In the present invention, an additional S electrode is added in the conventional three-electrode structure, and the discharge area is shorted by shorting the original S electrode and the added electrode. The four-electrode configuration of the PDP and the discharge maintenance method of the four-electrode PDP are proposed. Of the PDP driving apparatus having a four-electrode structure is S ₁ electrode, S ₂ electrode, made of a Y electrode and the addressing electrode positioned between the above-described S ₁ electrode and S ₂ electrode, the S in the _first electrode and S ₂ electrode The present invention relates to a four-electrode PDP driving apparatus in which an input portion of an electrode is shorted to form the same waveform.

Description

4-electrode PD drive

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a PDP driving device of a Plasma Display Panel Television. A four-electrode PDP driving device (4 elecrtic pole for plasma display) is used to increase the discharge area of the PDP gray scale process in a four-electrode PDP driving device. panel driving apparatus).

In general, the electrode structure of a PDP is classified into a direct current type, an alternating current type, and a mixed type in which a direct current type and an alternating current type are combined. In the case of a direct current type PDP, an electrode is directly exposed to the discharge plasma. In the case of an AC type PDP, the electrode is indirectly coupled with the plasma through a dielectric. As described above, the discharge type represents the direct current type and the alternating current type, and in the case of the AC type, charged particles formed by the discharge are accumulated in the dielectric layer. In other words, electrons are accumulated by the dielectric layer on the positively charged electrode, and ions are accumulated in the dielectric layer on the negatively charged electrode. The potential formed through this phenomenon is called a wall potential, and since the wall potential is formed to be opposite in polarity to the potential applied from the outside, when the wall potential is started again, the potential applied to the gas in the cell decreases. Therefore, when a sufficiently large wall potential is formed, the discharge is erased because the potential applied to the gas decreases below the potential at which discharge can be maintained. However, if the potential of the potential applied to the external electrode is applied after the wall potential is formed, the potential by the wall potential and the externally applied potential are added to discharge even when a low externally applied potential is applied. This phenomenon is called a memory function. The AC PDP has a memory function effect due to the wall potential accumulated in the dielectric. In other words, the dielectric in the cell where the discharge was previously formed may cause the charged particles to form a wall potential at the dielectric, thereby causing the discharge at a lower voltage than in a cell without the wall potential.

1 is a cross-sectional view of a conventional three-electrode PDP cell. As shown in FIG. 1, the cross-sectional view of the three-electrode PDP cell is shown in the front substrate 10, back substrate 90, S electrode 80, Y electrode 70, dielectric layer 60, magnesium oxide 50, The phosphor layer 30, the addressing electrode 20, and the partition 40 are comprised.

On the back substrate 90, a dielectric layer 60 for forming a capacitively coupled discharge covers the electrode, and two electrodes of the S electrode 80 and the Y electrode 70 are disposed on one substrate so that the S electrode 80 is disposed. And a discharge are formed between the Y electrode and the 70 electrode. On the other hand, since discharge occurs on one substrate, there is no ion shock in the phosphor layer 30, and there is an advantage that magnesium oxide is not used as the protective layer. However, since two electrodes of the S electrode 80 and the Y electrode 70 which form a discharge on the same substrate are respectively covered by the dielectric layer 60, the parasitic coupling capacitor value formed on each electrode and the dielectric becomes large. In general, the time constant of the resistor and the capacitor (RC) is increased, the operation speed is lowered, but it is solved by introducing three electrodes to separate the address operation and the sustain operation.

A necessary condition for forming a discharge is two electrodes, and an electrode structure having three electrodes is mainly used. In the case of the DC type, an auxiliary anode for forming an auxiliary discharge is added. In the case of the AC type, an addressing electrode is introduced to separate the selective discharge and the sustain discharge to improve the address speed. Therefore, the electrode structure may be classified into a two-electrode structure and a three-electrode structure according to the number of electrodes.

In addition, a barrier rib shown in a cross-sectional view of the three-electrode PDP cell determines the distance between electrodes for forming a discharge, and serves to prevent crosstalk due to discharge occurring in adjacent cells.

In general, the dielectric is boron silicate (borosilicate) series, because the secondary electron emission coefficient is low and the lifetime is shortened by sputtering by ions generated during plasma formation, magnesium oxide (MgO) to protect the dielectric from the plasma An oxide based thin film is coated on the dielectric layer as a protective film. Magnesium oxide coated on the dielectric layer exhibits low voltage discharge characteristics because of its good sputter resistance and high secondary electron emission coefficient. However, since the thickness of the magnesium oxide layer should be as thin as thousands of, and the surface characteristics should be excellent, it is difficult to form through thick film printing, and is usually manufactured by a thin film process by vacuum deposition.

The driving operation of the PDP having the electrode structure as described above uses a row driving method using a strong nonlinearity characteristic of gas discharge, unlike a cathode ray tube in which an electron gun sequentially scans pixel by pixel. In addition, the PDP is generally driven by a continuous pulse having a constant voltage, and gradation display is implemented by digital rather than analog. However, since gas discharge usually requires a relatively high voltage of several hundred volts, the video signal is amplified and driven.

In addition, the driving operation of the PDP is classified into three types and will be described below for better understanding.

First, erasing mode (Erasing mode) is an operation mode for erasing the discharge, in the case of AC PDP neutralizes the wall charge to form a discharge at a low voltage to prevent the wall charge is formed sufficiently, or erase with a short pulse width The wall charge is removed by applying a pulse to prevent the wall charge from reaching a steady state.

Secondly, an addressing or writing mode is a driving operation required for initial discharge formation. In the case of the He + Xe and Ne + Xe penning mixtures commonly used in PDPs, potentials of 240 to 280 volts are applied. The AC type composed of the third electrode reduces the high current caused by the parasitic capacitor caused by the sustain electrode and the dielectric, and adopts a driving method that separates the selection operation from the holding operation.

Third, the sustain holding operation is a driving operation in which the discharge is maintained by the sustain pulse having a voltage lower than the selection pulse by using the memory function characteristic of the gas discharge. In the case of an alternating PDP, a memory driving effect by wall charge is used, and a memory driving method capable of separating a selection operation and a holding operation by using the memory function is used to implement a high quality display device of a large PDP. Provided is a driving method capable of operating without high luminance in high gradation display.

On the other hand, the driving technology of the PDP is an active light emitting display device in which ultraviolet rays generated from gas discharge excite a fluorescent film to implement an image. That is, since the PDP uses ultraviolet light emission by gas discharge as a light source corresponding to each pixel, the driving circuit merely functions to form or erase gas discharge for each pixel in order to implement a display image. The driving circuit includes an image signal and signal control unit for each pixel constituting an image, and a high speed high voltage switching control unit that can form or eliminate ultraviolet rays generated from each pixel.

In addition, the row driving method refers to a method of simultaneously driving one line of cathode rays. That is, because of the nonlinear characteristics, if a scan pulse is applied to one cathode line and then a data pulse is applied to all the lines of the anode line, the voltage between the selected cathode line and the anode line does not reach the discharge formation voltage. Compared with the horizontal resolution, the brightness and efficiency are improved. That is, the row driving method is an essential method for driving a large display, and PDP is advantageous for large size because it has stronger nonlinearity than other display devices.

In the conventional three-electrode PDP panel as described above, the spacing between the electrodes becomes wider as the size of the PDP television increases. For example, in a PDP panel having a resolution of 853 x 480, the distance between electrodes becomes 40 inches wider than that of 30 inches. Therefore, when the distance between the electrodes of the PDP panel increases, the luminance is lowered and the discharge start voltage required for the PDP discharge is increased. In order to solve the above problems, the applicant filed in the patent application issued by the present applicant has proposed an invention to increase the discharge area by adding one more S electrode in the three-electrode method of the conventional S electrode, Y electrode and addressing electrode. . However, the invention presented in the applicant's prior application is arranged in the order of S1 electrode-Y electrode-S2 electrode so that the discharge is alternately made between S1 electrode and Y electrode, S2 electrode and Y electrode, so that the discharge area is Although improved than the three-electrode method, since the discharge occurs alternately, the size of the discharge area seen in time ratio has not been greatly improved.

The present invention has been invented to solve the problems of the prior art, an object of the present invention is S electrodes, Y electrodes, and address the S electrode in a conventional three-electrode structure having an electrode to add one more S ₁ electrode, Y The present invention provides a device for maximizing the discharge area of a PDP by configuring a four-electrode structure having an electrode, an S ₂ electrode, and an addressing electrode, and shorting the input portions of the S ₁ electrode and the S ₂ electrode to simultaneously apply an input voltage.

1 is a structure of a conventional three-electrode PDP electrode

Figure 2 is a block diagram of a conventional four-electrode PDP driving apparatus

3 is a structure of the four-electrode PDP electrode of FIG.

4 is a driving waveform diagram of the four-electrode PDP driving apparatus of FIG.

5 is a block diagram of a four-electrode PDP driving apparatus of the present invention;

6 is a driving waveform diagram of the PDP driving apparatus of the present invention of FIG.

<Description of the reference numerals for the main parts of the drawings>

10: front substrate 20: addressing electrode

30 phosphor layer 40 partition wall

50: magnesium oxide 60: dielectric layer

70: Y electrode 80: S electrode

90: back substrate 100: injection / maintenance drive

200a, 200b: Scan / Maintain IC IC 300: Address Drive IC

400: discharge holding unit 500: PDP panel

600: timing controller 700: discharge cell

700a: S1 electrode 700b: S2 electrode

700c: Y electrode 700d: addressing electrode

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the embodiment of the present invention. In order to facilitate understanding of the present invention, a four-electrode PDP driving apparatus will be described first. 2 is a block diagram of a peripheral circuit of a PDP driving apparatus having a four-electrode structure according to the present invention, which is disclosed in the patent application filed by the present applicant.

A timing controller 600 for supplying a control signal to each part of the system for PDP gradation processing, a line / scan driver 100 for supplying a voltage according to the control signal of the timing controller 600, and the line / Scan / hold driver ICs 200a and 200b for receiving a driving signal from the scan driver 100 and applying a voltage to the S1 electrode 700a and the S2 electrode 700b of the PDP panel 500, and the timing controller (see FIG. A discharge holding driver 400 for supplying a discharge voltage to the Y electrode 700c of the PDP panel 500 by receiving a control signal of the 600 and a control signal of the timing controller 600. And an address driver IC 300 for supplying a discharge voltage to the addressing electrode 700d.

The operation of the PDP driving apparatus of the four-electrode structure will be described schematically. The scan / hold driver 100 applies control signals suitable for driving the S ₁ electrode and the S ₂ electrode to the scan / hold driver ICs 200a and 200b, respectively. The control signals applied to the scan / sustain driving ICs 200a and 200b are converted into constant driving signals and applied to the S ₁ electrode 700a and the S2 electrode 700b, respectively. In addition, the discharge holding driver 400 applies a control signal to the Y electrode for driving the Y electrode 700c. In addition, the control signal for selective writing of the addressing electrode 700d is applied to the address driver IC 300 and applied to the addressing electrode 700d.

In the scan / hold driving ICs 200a and 200b, a sustain pulse is alternately applied between the S ₁ electrode 700a and the Y electrode 700c and the Y electrode 700c and the S ₂ electrode 700b. The driving of the discharged pixel is started and maintained. In addition, the address driver IC unit 300 sequentially receives image data to be written to the PDP panel 500, and loads one line of image data while shifting in parallel. Since the above process should be equal to the input mode operation time of the other temporary storage area, the input mode should be operated at twice the frequency of the output mode.

The S ₁ electrode 700a connected to the output terminal of the scan / hold driver IC unit 200a, the S ₂ electrode 700b connected to the output terminal of the scan / hold driver IC unit 200b, and the discharge described above. A discharge cell 700 having four electrodes coupled to the output terminal of the Y electrode 700c and the address driver IC 300 connected to the sustain driver 400 is displayed on the display area of the PDP panel.

3 is a cross-sectional view of a PDP cell having four electrodes. 4 is a cross-sectional view of the four electrodes of the PDP cell of FIG. 3, the front substrate 10, the rear substrate 90, the S1 electrode 700a, the Y electrode 700c, the S2 electrode 700b, the dielectric layer 60, and magnesium oxide. 50, the phosphor layer 30, the addressing electrode 20 and the partition 40.

In the electrode structure of the AC type PDP shown in FIG. 3, the S ₁ electrode 700a, the Y electrode 700c, and the S ₂ electrode 700b are formed on the upper surface of the back substrate 90, and are used for forming a capacitively coupled discharge. The dielectric layer 60 covers the S ₁ electrode 700a, the Y electrode 700c, and the S ₂ electrode 700b. In general, the dielectric used is boron silicate series, and because the secondary electron emission coefficient is low and the life span due to sputtering by ions generated during plasma formation is short, a thin film of magnesium oxide 50 is used to protect the dielectric from plasma. It is coated on the dielectric layer 60 with a protective film. In addition, the addressing electrode 700c separates the selective discharge and the sustain discharge to improve the address speed, and employs a method of exciting the phosphor like a cathode ray tube to colorize the PDP. Therefore, the phosphor layer 30 is applied to color the electrode structure of the PDP. On the other hand, the partition wall 40 determines the distance between the electrodes for forming the discharge, and serves to prevent mutual interference due to the discharge generated in the adjacent cells.

The four-electrode structure of the PDP configured as described above has a much shorter distance between electrodes than the three-electrode structure, and the four-electrode discharge cell 700 has a first discharge formed between the S ₁ electrode 700a and the Y electrode 700c. In addition, a second discharge is formed between the Y electrode 700c and the S ₂ electrode 700b, and the first and second discharges are alternately performed.

4 schematically illustrates a repeating fundamental waveform among waveforms in which a wall potential is formed according to an applied voltage pulse. The discharge start in the discharge cell occurs at the portion where the edge portion of the pulse of the S1 electrode and the edge portion of the pulse of the Y electrode meet each other. Therefore, discharge starts at the falling position of the pulse of the S1 electrode and the rising position of the Y electrode pulse. Subsequently, discharge starts at the falling position of the Y electrode pulse and the rising position of the S2 electrode pulse. This process is repeated to perform PDP gradation processing.

Hereinafter, referring to the four-electrode PDP driving apparatus described above, the four-electrode PDP driving apparatus of the present invention will be described. 5 is a schematic block diagram of a four-electrode PDP driving apparatus of the present invention. For the same part of the configuration, the reference numerals added in FIG. 2 of the conventional four-electrode method described above will be used as they are.

A timing controller 600 for supplying a control signal to each part of the system for PDP gradation processing, a line / scan driver 100 for supplying a voltage according to the control signal of the timing controller 600, and the line / A scan / hold driver IC 200 for receiving a driving signal from the scan driver 100 to apply a control signal to the S1 electrode 700a and the S2 electrode 700b of the PDP panel 500, and an input for receiving the control signal In addition, the PDP panel (S1 electrode 700a and S2 electrode 700b and the control signal of the timing controller 600 are received by the short-circuit and simultaneously receive the same control signal from the scan / hold driver IC 200. The discharge sustain driver 400 for supplying the discharge voltage to the Y electrode 700c of the 500 and the control signal of the timing controller 600 are applied to discharge the discharge voltage to the addressing electrode 700d of the PDP panel 500. The address driver IC 300 is supplied.

The operation of the four-electrode PDP driving apparatus in which the input unit of the present invention is short-circuited will be described. The scan / hold driver 100 applies a control signal suitable for driving the S ₁ electrode and the S ₂ electrode to the scan / hold driver IC 200, respectively. The control signals applied to the scan / sustain driving ICs 200 are converted into constant driving signals and simultaneously applied to the S ₁ electrode 700a and the S2 electrode 700b having a common input unit. In addition, the discharge holding driver 400 applies a control signal to the Y electrode for driving the Y electrode 700c. In addition, the control signal for selective writing of the addressing electrode 700d is applied to the address driver IC 300 and applied to the addressing electrode 700d.

The scan / maintenance IC 200 applies a sustain pulse alternately between the S ₁ electrode 700a and the Y electrode 700c and the Y electrode 700c and the S ₂ electrode 700b, thereby causing wall charge. The driving of the discharge of the formed pixel is started and maintained. In addition, the address driver IC unit 300 sequentially receives image data to be written to the PDP panel 500, and loads one line of image data while shifting in parallel.

Y connected to the discharge maintaining driver 400 and the S ₁ electrode 700a and the S ₂ electrode 700b connected to the output terminal of the scan / hold driver IC unit 200 as one common input terminal as described above. The discharge cell 700 having four electrodes coupled to the electrode 700c and the output terminal of the address driver IC unit 300 performs PDP gradation processing by discharge to display an image.

6 is a waveform of the generated pulse of each electrode in the four-electrode PDP driving apparatus according to the present invention. Compared with FIG. 4 which shows the output waveform and the discharge phenomenon of each electrode when the inputs of the S1 electrode and the S2 electrode are independently discharged with the Y electrode, the input of the S1 electrode 700a and the S2 electrode 700b is described. By short-circuiting and receiving the same input signal at the same time, the waveforms of the S (S1, S2) electrodes appear as pulses with a repeating fundamental waveform. Since the discharge phenomenon occurs at the edge of the pulse in the pulse of the Y electrode 700c corresponding to this, the discharge does not occur alternately, but the discharge continues to occur every pulse, thereby acting to expand the time-rate discharge area. .

As described above, in the present invention, a driving apparatus of a PDP having a four-electrode structure in which a S electrode is further added to the conventional three-electrode PDP structure includes an S ₁ electrode, an S ₂ electrode, and a space between the S ₁ electrode and the S ₂ electrode. It consists of a Y electrode and an addressing electrode located in the S ₁ electrode and the S ₂ electrode has the effect of maximizing the discharge area of the PDP by shorting the input portion of the electrode so that the same waveform is formed, thereby increasing the brightness of the PDP large There is an effect to improve.

Claims (2)

A timing controller 600 for supplying a control signal to each part of the system for PDP gray level processing; A line / scan driver 100 for supplying a voltage according to the control signal of the timing controller 600; A scan / hold driver IC 200 receiving a drive signal from the line / scan driver 100 and applying a control signal to the S1 electrode 700a and the S2 electrode 700b of the PDP panel 500; An S1 electrode 700a and an S2 electrode 700b which are short-circuited by the input unit and simultaneously receive the same control signal from the scan / hold driver IC 200 to one common input unit; A discharge holding driver 400 for supplying a discharge voltage to the Y electrode 700c of the PDP panel 500 by receiving the control signal of the timing controller 600; The four-electrode PDP driving apparatus comprising an address driver IC 300 for supplying a discharge voltage to the addressing electrode 700d of the PDP panel 500 by receiving the control signal of the timing controller 600. The four-electrode PDP driving apparatus according to claim 1, wherein the S1 electrode 700a and the S2 electrode 700b generate the same continuous pulse in one repetition section.